ライフサイエンスコーパス: polysulfone

1 erephthalate (PEOT/PBT) block copolymer, and polysulfone.

2 polyethylene terephthalate, polyisoprene and polysulfone.

3 dialysis with CTA (10.91 +/- 3.65 ng/mL) and polysulfone (10.73 +/- 2.24 ng/mL) dialyzers were signif

4 ining ion-exchange particles with sulfonated polysulfone as a binder.

5 With polysulfone as an example, we demonstrated the feasibili

6 ed phenomenon, wherein a demonstrably stable polysulfone backbone degrades rapidly in alkaline soluti

7 e addition of PVP as hydrophilic modifier to polysulfone-based membranes increases the biocompatibili

8 hese enzymes have been co-immobilized into a polysulfone/carbon nanotubes/ferrocene membrane by means

9 fabricated polymer membranes were evaluated: polysulfone, cellulose acetate, polyvinylidene fluoride

10 eters by approximately 5 A, so that a single polysulfone chain has an apparent diameter of 9-12 A in

11 cm(-2) with diamine crosslinked quaternized polysulfone (DAPSF) binder at 80 C with 90% humidified H

12 Cs increased after chronic hemodialysis with polysulfone dialyzers (from 0.039+/-0.002 to 0.043+/-0.0

13 ents on hemodialysis: 28 patients started on polysulfone dialyzers and were switched to polynephron d

14 ncreased after one hemodialysis session with polysulfone dialyzers but not with polynephron dialyzers

15 Chronic (3-month) use of polysulfone dialyzers did not significantly increase pre

16 Furthermore, chronic hemodialysis with polysulfone dialyzers increased oxidative stress in PBMC

17 p dialysis circuit with either new high-flux polysulfone dialyzers or dialyzers reprocessed once or 2

18 trate that dialysis with cellulose, CTA, and polysulfone dialyzers results in a significant increase

19 s demonstrate that reprocessing of high-flux polysulfone dialyzers with bleach increases the risk of

20 g/mL, respectively, with cellulose, CTA, and polysulfone dialyzers, and postdialysis levels were 17,8

21 , and 3790 +/- 1151% for cellulose, CTA, and polysulfone dialyzers, respectively.

22 f predialysis ratios for cellulose, CTA, and polysulfone dialyzers, respectively.

23 n polynephron dialyzers and were switched to polysulfone dialyzers.

24 cellulose, cellulose-tri-acetate (CTA), and polysulfone dialyzers.

25 o dialysis with new or reprocessed high-flux polysulfone dialyzers.

26 fficiency" cellulose (T220L) and "high-flux" polysulfone (F80B) dialyzers reprocessed with formaldehy

27 st record of a microplastic in Antarctica, a polysulfone fiber ingested by a Boreomysis sp. mysid cau

28 kD nominal molecular weight cut-off (MWCO), polysulfone fibers with 400 kD MWCO, and mixed cellulose

29 ous hemodialysis in 50-min intervals using a polysulfone filter (1.2 m2; mean pore size, 0.50 nm; blo

30 A tubular microdialysis probe is made from polysulfone hollow fibre for human haemodialysis, which

31 ound that some polymers such as PEOT/PBT and polysulfone interfere with islet function.

32 Eventually, the polyamide (and polysulfone) layer can rupture, resulting in the irrever

33 ketone, amine, hydroxyl, and aldehyde to the polysulfone main chain in excellent conversion.

34 monstrate that physical diffusion across the polysulfone membrane does not alter the carbon isotope v

35 separator consists of an asymmetric, porous, polysulfone membrane housed in a disposable chamber.

36 al disease over a period of one year using a polysulfone membrane water gravity-powered water filtrat

37 Using a 3-cm-long polysulfone membrane with averaged molecular weight cuto

38 In vitro, polysulfone membranes released significantly more BPA in

39 ated contained either modified cellulosic or polysulfone membranes, whereas the germicides examined i

40 d the effect of dialysis with BPA-containing polysulfone or BPA-free polynephron dialyzers on BPA lev

41 osite (using polyamide, polyethersulfone and polysulfone polymers) as a membrane was fabricated to re

42 as to investigate if the treatment of porous polysulfone (PPSF) with various concentrations of platel

43 Culture on PEOT/PBT and polysulfone profoundly disturbed function of islets, and

44 polymeric dialyzer membranes, consisting of polysulfone (PS) and polyvinylpyrrolidone (PVP), were in

45 thicknesses using the synthesized pTAP with polysulfone (PS).

46 luorescens, a biofilm-forming bacterium, and polysulfone (PSF) ultrafiltration (UF) membranes to unra

47 ing MEA performance with quaternary ammonium polysulfone (QAPS) binder at the same operating conditio

48 edicted membrane-solvent compatibility, with polysulfone (RED = 0.6) and cellulose acetate (RED = 0.9

49 tly connected to the pores of the underlying polysulfone substrate.

50 The air pockets between the polysulfone support and the polyester backing layers, wh

51 rbonyl trichloride, on a polydopamine-coated polysulfone support.

52 A) bilayers on a polydopamine-functionalized polysulfone support.

53 abluminal membrane surface consists more of polysulfone than polyvinylpyrrolidone, and the luminal m

54 nce of helical regions in these freeze-dried polysulfones thus reflects their solution conformations

55 pin)(2)] to form the corresponding borylated polysulfones up to high concentrations with nearly const

56 Similarly, postdialysis levels with CTA and polysulfone were significantly greater (P < 0.05) than t

57 ld, iridium-catalyzed borylation of aromatic polysulfone with bis(pinacolato)diboron [B(2)(pin)(2)] t

58 ra cross-coupling reactions of the borylated polysulfones with functionalized aryl bromides allows in